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Conveyor chain
Installation, maintenance& designer guide
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2 I Installation, maintenance & designer guide
RollerChain
British, ANSI, API, DIN, ISOand Works Standard Chains
Adapted Chains
Extended Pitch Chains
Hollow Pin Chains
Made to Order, Special Chains
Mini Pitch Chains
Nickel Plated ChainsOilfield Chains
Plastic Bush Chains
Power and Free Chains
Polymer Block Chains
Side Bow Chains
Stainless Steel Chains
Applications
Abattoirs Air Conditioning Aircraft - Civil & Military Bakery Machines Battery Manufacturing
Brewing Canning Carpet Machines Chart Tables/Marine Chocolate Manufacturing
Concrete Moulding Equipment Copying Machines Dairy Machinery Drying Machinery
Earth Moving Equipment Extrusion Machines Filtration Plants Food & Drink Manufacture Glass Manufacture Health Care Equipment Hydraulic Components Ice-Cream Manufacture
In-flight Refuelling Ingot Casting & Scrap Metal Processing Latex Machinery LaundryMachinery
Lawnmower Manufacture Mill Machinery Mining MOT BrakeTesting Machinery Nuclear Power
Off Road Vehicles Oil Industry Packaging Machines Paper & Card Making Paper Shredders
Plastic Machinery Potato GradingMachinery Power Generation PrintingMachines Quarry Plant
RoadMaking& Plant Machinery RoboticSystems RoofTileManufacture Ship's Engines
Silkscreen Machinery Ski-Lifts Soot Blowers Steel Making StraddleCarriers Sugar Beet Machines
Sun-Blinds Telecommunications Textile Machinery Timber and Woodworking Machines
Tin Printer Ovens Tobacco/Cigarette Machinery Tunnelling Machines T.V. and Audio Equipment
Tyre Manufacture Waste Handling X-Ray Equipment
ConveyorChain
British, ISO and Works
Standard ChainsAdapted Chains
Agricultural Chains
Bakery Chains
Deep Link Chains
Escalator Chains
Made to Order, SpecialsStainless Steel Chains
Sugar Cane Chains
Zinc Plated Chains
Applications
Abattoirs Agricultural Machines Bakery Machines Bottle Washing Plants
Brick & Tile Machinery OEM Car Plants Cement Plants ChemicalPlants ChickenProcessEquipment
Cigarette/Tobacco Machinery Dust Filters Egg Sorting Conveyors Electrical Switchgears Escalators
Extrusion Machines Feed Mill Machines Feed Silo Equipment Fibreglass Industry Filtration Plants
Fish Conveyor Food Sterilisation Food Processing Freezing Equipment Freezing Tunnels Glass
Manufacturing Grain Conveyor Harvesting Machines IceCream Machines InductionFurnaces Ingot
Casting& Scrap Metal ProcessingMfr LatexMachinery Leisure Rides Luggage& ParcelHandling
MachineTools MailSorting Metal Casting Mushroom Compost Machinery Nuclear Ovens/Provers Potato Grading Machinery Potting Machinery Quarries Radio Astronomy Roof Tile Manufacture
Rope Machinery Saw Mill Equipment Sewage Plants Shaker Conveyors Ski-Lifts Sluice Gates
SteelMaking Sugar Factories SwarfConveyors Textile Machinery Timber & WoodworkingMachines
Tool Changer Tunnelling Machines Tyre Manufacture Washing & Sterilising Machines
Water Treatment Wire Belts
Lifting Chain
LH(BL), AL, LL and Works Standard Chains
Applications
Bottle Washing Plants Cement Plants Chemical Counterbalance Sets Cranes
Dust/Swarf Conveyors Elevators Food Processing Food Sterilisation Fork Lift Trucks
Pipe Line Valves/Taps Printing Machines Rock Drilling Straddle Carriers Sun-Blinds Tail Lifts
Renold Chain Product Range
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Installation, maintenance & designer guide I 3
Table of Contents
Section 1 - Conveyor Chain Installation and Maintenance
Installation and Maintenance guidelines and advice 4-20
Section 2 - Conveyor Chain Designer Guide
Specification guidelines and advice 21-61
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4 I Installation, maintenance & designer guide
Section 1Conveyor Chain
Installation & Maintenance
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Chain Installation and MaintenanceIntroduction
Renold has, for many years, been a leader and
innovator involved in the design andmanufacture of standard conveyor chain andthe development of engineered products forsuch applications as escalators, travelators,sterilizers, cement conveyors, leisure rides andnumerous other specialised systems for themechanical handling industry. We have adetailed understanding of the maintenanceneeds on such applications and can now offerthe manufacturers and operators of conveyorsystems the benefits of this knowledge.
Chain is one of the most widely used movingmediums in mechanical handling systems,being robust and very adaptable, but it is alsoone of the most neglected components within
such equipment when general or routinemaintenance is carried out. In many cases thisproduct is attended to when problems occur,normally when the chain is already damagedand the only real option is to fit a replacementto the system.
This section has been designed with themanufacturer and operator in mind. It coversthe functional aspects of using Renold conveyorchain and emphasizes the correct use ofpreventative maintenance procedures, whichwill ensure better machine performance, lessdown time, lower overall maintenance costsand extended chain life.
Installation of New Chain
When installing a complete set of new chainsthe method of installation depends on thestate of the conveyor, i.e. if the old chain is stillin place, or the chain has been removed toallow refurbishing of the sprockets, tracks etc.
Old Chain Still In Place
On some installations where sprocket and trackwear are minimal e.g. escalators, it is possibleto replace the chain as the old chain isremoved.
Any fixtures, slats, steps, buckets etc., whichjoin two or more chains should be removed,except for enough to keep the chains at thecorrect spacing. The chains should then bebroken at the tension end by removing anouter link or connecting link as necessary.Handling lengths of the new chains can thenbe attached to the old chains using oldconnecting links if possible. Care should betaken to ensure that the chains are in thecorrect orientation. New fixtures should beconnected to the new chain or old fixturesshould be reconnected to maintain chain crosscentres.
The drive can then be used to inch the newchains on and the old chains off.
When the new chains have been fed onto theconveyor the next new handling lengths can beattached, this time using new connecting links.At the same time, the old chain can bedisconnected from the lower strands. Repeatuntil all the chain has been replaced.
No Chain in Place
Where the conveyor has no chain in situ, (i.e.after refurbishing tracks etc., or a newconveyor), the method of installing chainshould be decided according to conveyor layout,access available and equipment available. Thefollowing notes are intended as a guide only.
Horizontal & Inclined Conveyors
Where possible, chain should be fed on at thetake-up end of the conveyor and pulled up tothe drive end. When enough chain has beeninstalled to fill up to the drive, the chain canthen be inched over the drive sprocket and intothe return tracks. Care should be taken to makesure that the chain is always restrained andcannot run back.
NOTE: On horizontal conveyors, chain can befed into the return tracks either over the driveor take-up wheels.
On inclined conveyors the chain will need to behauled up using a block and tackle, 'Tirfor' orwinch (Fig. 1). Care should be taken to make
sure that the chain is always restrained andcannot run back. On twin strand conveyorswith slats/buckets etc., where access isavailable at the end of the conveyor, the chainhandling lengths can be fully assembled withslats/buckets etc. before being installed on theconveyor and then be drawn in as completeunits.
Fig. 1
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Bucket Elevators
On light duty elevators it may be possible, ifaccess and space are available, to install thechain from the top of the elevator and join thechain at the drive sprocket.
On heavy duty elevators (usually twin strand) itmay be necessary to fully or partially assemblethe chains and buckets in handling lengths andlift them up through the bottom of the casing(Fig. 2). When enough chain has beenassembled to reach the drive sprockets it caneither be fed over the sprockets and drivendown as more chain is installed and then
joined at the bottom, or it can be secured atthe top and the opposite side hauled up and
joined at the top and the bottom.
Assembly & Installation
When assembling new chain or repairingexisting chain, the following precautions arenecessary.
a) All power to the conveyor should beisolated before any work is started on thechain.
b) Care should be taken to identify the chainand to ensure that correct replacementlinks are at hand before breaking the chain.
c) The chain tension should be slackened off
completely so that joints are loose.d) The sprockets should be prevented from
rotating whilst working on the chain,especially on inclined conveyors orelevators.
e) The chain should be suitably restrained onboth sides of the link to be broken, orconnecting link to be removed.
f) The correct working practices should beemployed at all times.
NOTE: Great care should be taken to securechain properly in elevators to prevent it falling
down inside the casing.
The following points are also important and
should be adhered to:-
i) The necks of connecting pins should not beground or filed to ease insertion into thechain plates, nor should the plate holes berelieved. The press fit is an essential part ofthe chain construction and should not bedestroyed.
ii) Do not apply heat to the connecting platesto ease insertion of the connecting pins.This could seriously damage the materialproperties.
Reconnecting Chain
The method of chain connection depends uponthe type of connecting link used. The main onesare either solid pin (i.e. No. 107, 58, 69, 86), orhollow pin (No. 107).
Whichever type is used, the following steps arerecommended:-
Solid Pin Connectors
a) Secure the chain on both sides of theassembly point.
b) Unless the chain has to run unlubricated,coat the connecting pins with grease or oiland insert the pins into the two ends of the
chain.c) Place the loose plate over the ends of the
connecting pins and support the fixed plateside of the chain against the assemblyforce.
d) Progressively force the loose plate onto theconnecting pin necks equally andalternately, using a hollow punch andhammer or a hydraulic press or jack.(See Fig. 3).
e) When the plate is fully seated, apply theconnector e.g. nut, split pin or circlip, orrivet the pin end. (See following notes onriveting).
f) Check that the assembled joint flexes
freely. If it is tight, a light blow on theopposite end of the connecting pins shouldfree the joint.
Hollow Pin Connectors
a) Secure the chain on both sides of theassembly point.
b) Unless the chain has to run unlubricated,coat the hollow pins with grease or oil andinsert the pins into the two ends of thechain.
c) Place the loose plate over the ends of thehollow pins and support the chain on the
fixed plate side against the assembly force.d) Progressively force the loose plate onto the
hollow pin necks equally and alternately,using a hollow punch and hammer, ahydraulic press or jack, or a bolt and spacertype tool. (Fig. 4).
e) When the plate is fully seated, rivet the pinends (see following notes on riveting).
f) Check that the assembled joint flexesfreely. If it is tight, a light blow with ahammer on the opposite end of thehollow pins should free the joint.
Fig.2
Fig. 3
Fig.4
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Chain Installation and Maintenance
Riveting Solid Pins
To rivet a solid bearing pin, the chain should besupported on the opposite end of the bearingpin against the riveting force. On very smallbearing pins, a couple of sharp taps with ahammer on the end of the pin will be enoughto spread the rivet end. However, on largerbearing pins (i.e. 7500lb (33kN) breaking loadand above) this will not be satisfactory. Theoutside edge of the pin needs to be peenedover to form a satisfactory rivet. (Fig. 5).A hammer blow directly on the end of theselarger pins will not be enough to accomplishthis.
This can be done with:-
a) A hammer, working around the pin head.(Care should be taken to hit the bearing pinedge and avoid damaging the link plate)(Fig. 6).
b) Work around the pin head with apneumatic hammer.(Again avoid damaging the link plate).
c) A riveting punch and hammer,progressively turning the punch after eachblow of the hammer to peencompletely around the bearing pin head(Fig. 7). Use the factory riveted pins as aguide to rivet spread.
Riveting Hollow Pins
As for solid pins, the chain should be supportedon the opposite end of the pin against theriveting force. The end of the bearing pin thenneeds to be slightly expanded to prevent theplate working off the pin. This can be doneusing a conical ended drift or a radiused punchand a hammer. Use the factory assembled pinsas a guide to rivet spread. (Fig. 8).
NOTE: When riveting chain, observe normalsafety precautions. Wear safety glasses andprotective clothing and make sure tools are ingood condition and properly used.
Adjustment
Once the chain has been installed and all thefixtures are in place, adjustment of the chainwill be necessary before the chain is run. Caremust be taken that the chain is not overadjusted, as this will add pre-tension into thechain which will in turn reduce chain life.
The main requirement of chain adjustment isto remove slack from the chain (i.e. to take upthe clearances between the pins and bushes ineach link). Pre-tensioning of the chain is notrequired.
On the majority of conveyors, a screw typetake-up unit is used (see Fig. 9) due to itssimplicity and lower cost. On this type of unit it
is easy to keep on turning the adjustmentscrews and pre tension the chain, so great careis needed.
Fig. 5
Fig.6
Fig.7
Fig. 8Fig.9
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Chain Installation and MaintenanceMaintenance Schedule
A typical maintenance schedule is laid out
below. This should be adapted to suit eachspecific application, based on the localconditions and duty cycle.
Typical Maintenance Schedule
EVERY WEEK
Check lubrication and lubricate if necessary.
FIRST MONTH'S RUNNING
Check chain take-up and adjust if necessary.
Check for unusual wear and identify causeand rectify.
AFTER 3 MONTHS
Check chain adjustment and rectify ifnecessary.
Change oil, oil filter and clear the sump, iflubrication system fitted
EVERY 3 MONTHS
Check chain take-up and adjust if necessary.
Check unusual wear and identify cause andrectify.
ANNUALLY
Carry out the above checks.
Check for wear on side plates.
Check for chain elongation.
Check cleanliness of components.
- Remove any accumulation of dirt orforeign materials.
Check for shaft and sprocket alignment. Check for wear on sprockets.
Check the condition of the lubricant.
Check the lubrication system.
Lubrication
Effective lubrication of the chain bearingsurfaces is essential to obtain optimumperformance in addition to minimising powerabsorption, rate of wear, probability ofcorrosion and noise.
For normal conditions a good quality mineraloil with medium viscosity, for example SAE20W50, is recommended where operatingtemperatures are normal.
The standard treatment given to every Renoldchain before leaving the factory, unlessotherwise requested, is to immerse the chain ina grease which, when solidified, will act as aprotection and preliminary lubricant for the
chain. Re-lubrication should be carried outimmediately after installation of the chain witha suitable lubricant and at regular intervalsthereafter. The following selection procedurefor conveyor chain lubrication is designed togive users an idea of the types of lubrication tobe used in conditions where normal lubricantswould be inadequate. (See Fig 11).
Fig. 11
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Industry
Some industries will have special needs from aselected lubricant. These needs will usually bedetermined by the demands of the producthandled and the product susceptibility tocontamination and spoiling by direct or indirectcontact with lubricant. Some industries with
these special needs are listed and users shouldcontact lubricant specialists forrecommendations.
Marine Industry TobaccoCeramics SugarTextiles Hospital EquipmentFood Industry Nuclear EnvironmentWater
Temperature Considerations
Low temperature conditions -60C to 0C,require application of low temperature, waterrepellent grease to lubricate and preventcondensation water freezing and locking thechain. Low temperature lubricants are designedto be both lubricants and water repellents.They comprise synthetic oils in an organic orinorganic carrier. Lubrication is by means ofsynthetic polymers which, under load, formchains to provide a passive film on frictionsurfaces. They will not mix with, and activelyrepel, water. Temperature range -60C to
+120C.High temperature 100C to 450C.
Up to 160C a wet film lubricant is generallyused. Above 160C a suitable dry-film, non-carbonising lubricant is generally employed.
Wet-film, high temperature lubricants areusually solid lubricants (greases), which aredispersed in a chlorinated hydrocarbon solvent.This allows penetration of lubricant into criticalareas, after which solvent evaporation occurs.(Temperature range -25C to + 160C).
Dry-film, high temperature lubricants usuallyconsist of colloidal molybdenum disulphide orgraphite in a non-carbonising synthetic carrier.
This carrier penetrates into the critical areas ofthe chain and then evaporates, leaving a dryMoS2or graphite film. (Temperature range 0
to + 450C).
Dusty Conditions
Chain should be prelubricated before operationwith a suitable dry film lubricant to preventdust adhering to the lubricant. Periodically thechain should be cleaned and re-lubricated withthe same lubricant.
Chains fitted with grease gun lubricated pins
and bushes are most effective in theseenvironments.
Hot and Dusty Conditions
The same considerations should be used as fordusty conditions, but the dry film lubricant
should be chosen to be effective at theoperating temperature.
Water Environments-Clean
In water plants, chains are usually operatingabove water level and therefore requirelubricants that are effective, but sufficiently
adhesive to not fall into potential drinkingwater. Lubricants are available as special heavygreases and these are most effective whenapplied to the chain components during chainassembly. Water industry grease comprises ablend of mineral oil, graphite, hydrophobic andanti-corrosive elements. Each in its turn willlubricate, repel water and prevent corrosion.The grease will not dilute in water, is extremelyadhesive and actively repels water. The sameheavy duty greases are available for chainsoperating in water where contamination is nota problem. Regular regreasing is necessary inthis case. Water authority approval may berequired for lubricants used near drinkingwater.
Water Environments - Dirty
Chains operating in sewage treatment worksare frequently completely immersed and, otherthan a prelubrication, it is impossible tolubricate regularly. In these cases, chains areselected to operate sacrificially, or specialmaterials are selected to operate in a
continuously wet environment. Where chainsare accessible for lubrication, grease gunlubricated chains should be used with waterrepellent grease to periodically flush out theold grease and contaminants.
Solvent Environments
Where chains are operating in a solventatmosphere, then lubricants must be chosenwith great care. Regular re-lubrication is usuallynot possible due to removal of lubricant by thesolvent, causing solvent (and therefore product)contamination. Lubrication suppliers should beconsulted and a product obtained that will notbe dissolved by the solvent.
Other Wet Environments
These special environments must beindividually considered. Consult specialistlubricant supplier or contact Renold.
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Auto-Lube
The main types of auto-lube systems are dripfeed, single shot and oil mist spray. All systemsconsist of a fixed set of pipes, an oil reservoirand the necessary control valves and pumps.The purpose of the system is to automaticallydeposit an amount of oil in the chain as itpasses the oil discharge point. Drip feedsystems are usually gravity fed, but the singleshot and oil mist spray are usually pneumatic.
The system should be switched on once perday, once per week, or however necessary forone or two complete circuits of the chain toensure the bearing surfaces are satisfactorilylubricated. Unless the conveyor is part of a
process where the lubricant is continually beingwashed off the chain, the lubricator should notbe run continually.
Grease Gun
In certain applications, chain is designed forgrease gun lubrication. This chain has bearingpins and bushes cross drilled to allow thegrease to penetrate into the bearing surfaces(see fig. 13) from within the chain. Greasenipples are fitted to the ends of the bearingpins to allow grease to be injected into thechain. This has the advantage that any dirt orcontaminants that get into the chain are forcedout as the grease is injected.
This types of chain is pregreased at the factoryand can be re-lubricated either by manualgrease gun or by an automatic greaselubrication system. As with other methods, theregularity of re-lubrication depends on theenvironment and application of the chain.
Chain & Sprocket Storage
Chain
Before chain leaves the Renold factory it is pre-lubricated with a grease which acts as acorrosion protective and anti-fretting lubricant.For shipment they are either stacked on palletsand then shrink wrapped or packed intowooden boxes. If the chain is to be stored onsite for weeks or months before use, it shouldbe left in the packing for protection. It shouldnot be stored in an open area where dust, dirtand water are present. If chain equipment is tobe left idle for long periods, clean the chain andsprockets (i.e. brushing or steam cleaning) and
then cover them with oil. If chain is removedfrom a machine for storage, try to store it in acontainer filled with old engine oil or similar.Where it is not possible to store chains in alubricated environment, they should belubricated on installation and run unloaded forat least 24 hours.
Sprockets
Sprockets usually leave the works shrinkwrapped on pallets or in wooden boxes. Allsurfaces are painted before despatch exceptwhere they have been machined (i.e. cut teethor bored and keywayed). If the sprockets arenot to be used within a few days of receipt,
then all machined surfaces should be paintedwith a heavy oil or grease to prevent corrosion.As stated for the chain, do not store in an openarea where dust, dirt and water are present.
General Inspection
Chain needs to be checked on a regular basisthroughout its life, to ensure any faults in themachine are detected at an early stage so thatrectification work can be carried out to preventfurther damage.
Fig. 13
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Inspection of chain should not be left until a
major breakdown has occurred. This may resultin expensive replacement of major parts andlong down time if the required new parts arenot readily available.
On drive chain the major factor determiningchain life is extension due to wear between thebearing pin and bush. However, on a conveyorchain the life may be determined by wear onother components, depending on theenvironment in which the chain is used. Whereaccessible, the chain should be checked forwear as follows:-
Extension of Chain Pitch
A direct measure of chain wear is the extensionin chain pitch due to the wear between bearingpin and bush. This is caused by the chainarticulating under tension around the drivesprockets and can usually be obtained by directmeasurement as follows:-
Measure a length of chain over as many pitchesas possible. The chain must be on a straightsection of track and under tension. Thismeasured length "M" can then be applied tothe following formula to obtain the percentageextension.
The maximum allowable percentage extensionis shown in the following tables for the relevantseries of chains. When the chain extension hasreached this figure, the chain is due forreplacement. If regular measurements aretaken and results recorded, it is possible topredict how long the chain will last and whenreplacement will be required. The necessarysteps can then be taken to ensure the chain is
available and avoid any sudden panic.
Roller Wear
On long centred conveyors for example wherethe load is carried by the chain rollers runningalong a track, the rollers are continually turningunder load against the bushes. The pin andbush only turn against each other four timesper circuit of the conveyor (only one of theseis under full load). Under these circumstancesroller wear can be the limiting factor in
chain life.
An idea of the amount of roller wear can be
obtained by measuring the clearance betweenthe bottom of the link plates and the tracksurface and comparing the result with thatobtained on a new piece of chain. See Fig. 15.
If the rollers have worn to the point where thelink plates are near to or are rubbing on thetracks, then replacement is necessary. Ifstandard chain is fitted it is not possible toreplace just the rollers, therefore the completechain should be replaced. If outboard rollers arefitted then it may be possible to replace therollers only.
Where bends occur in the tracks, extra careshould be taken with roller wear assessment as
less wear is allowable before the link plateedges contact the tracks. See Fig. 16.
Link Plate Wear
Wear on link plates can appear in various ways,due to a number of different causes and insome cases can mean premature chainreplacement.
On scraper conveyors or conveyors where thechain runs on its link plate edges, wearing awayof the plate edges can occur, which will reducethe plate depth and thus the tensile strength of
the chain. (See Fig. 17).This wear should not exceed more than halfthe original plate depth above the bush,otherwise a chain breakage could occur. Whenwear has occurred to this extent the chainshould be replaced. In some cases, to extendchain life it may be possible to turn the chainover so that the unworn edge of the chainbecomes the wearing surface. This will dependon the type of chain, fixtures on the chain andthe make-up of the chain. (See Fig. 18).
Fig. 14
Where M = Measuring length (mm)X = Numberof pitchesmeasuredP = Chainpitch (mm)
Percentageextension = [M - (Xx P)] x 100X x P
Chain Allowable % Chain Allowable %
Series Extension Series Extension
BS Chains
3000lb 40.6 24000/30000lb 102(13KN) P (107KN/134KN) P
4500lb 40.6 36000/45000lb 102(20KN) P (160KN/200KN) P
6000/7500lb 50.8 60000lb 127(27KN/33KN) P (267KN) P
12000/15000lb 76.2 90000lb 127(54KN/67KN) P (400KN) P
ISO Chains
M40 76 MC224 128P P
M56 88 M315 168P P
MC56 71 M450 180P P
M80 102 M630 203P P
M112 97 M900 230P P
MC112 97P
Fig. 15
Fig. 16
Fig. 17
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The rubbing friction between the roller sideface and the inside of the inner links canproduce wear on the inner link plate. If thisoccurs before signs of wear on othercomponents, it is a sign of misalignment in theconveyor. In this case, roller treads should alsobe checked for signs of tapered wear.
(See Fig. 19).
Similar wear may occur between the inner andouter link plates (see Fig. 20) (although this isnot common on the BS series of chains, due tothe bush projection from the inner link plateswhich creates a gap between the inner andouter plates). Again, this is usually a sign ofmis-alignment. In both cases, if the platethickness has been reduced by more than 1/3of its original thickness the chain strength issubstantially reduced and the chain should bereplaced after first rectifying the mis-alignments.
i.e. Check the following:-
A) Alignment of head and tail wheels.B) Shaft alignments.C) Level across tracks.
If possible, the chain should be checked formarking or damage to the inner plate edgesand marking or wear on the inside faces of theinner links. This is due to the sprocket teethrubbing on the plates as the chain engageswith the sprocket. Light marking is usual, dueto normal movement of chain. However, ifwear is heavy and plate thickness is reducing,
sprocket spacing or alignment should bechecked and rectified and severely damagedlinks replaced.
Bush Wear
Unless the conveyor uses a bush chain (i.e.chain without rollers), it is not usually possibleto detect bush wear or damage withoutdismantling a piece of chain into its componentparts.
If a bush chain is used, checks should be madefor wear on the outside of the bush. This wearcould be due to either the bush sliding alongthe tracks or the bush gearing with the chainsprockets. If the bush is worn through so thatthe bearing pin is exposed, then the chainshould be replaced. In certain circumstances itmay be possible to turn the chain over andwear the opposite face of the bush to extendthe chain life. (In this case, advice from Renoldshould be sought).
Should any cracked or broken bushes be found,then the cause should be identified andrectified, then depending on the extent of thedamage, either links or the complete chainshould be replaced.
Bearing Pin Wear
Normal bearing pin wear shows up as pitchextension and can be detected as stated onpage 61.
Wear of the bearing pin heads can be caused byeither insufficient clearance between the chainand side guides, tracks not level across theconveyor causing the chain to run over to thelower level, chain twisted due to abuse, or badchain guidance.
The cause should be identified and rectified. Ifthe bearing pin heads have worn down levelwith the chain plates, then the rivet will beineffective and either the bad links or thecomplete chain should be replaced.
General
General visual inspection of the chain shouldbe carried out with the forgoing to detectbroken components, broken or damagedattachments, severe corrosion, seized joints orany unusual occurrences. The causes of theseshould be identified and rectified and damagedchain replaced.
Sprocket Tooth Wear
Normal wear takes place due to theengagement of the chain with the sprocketteeth and shows up as a polished or worn stripon the face of the tooth gap near the root (i.e.about the PCD). Wear generally occurs faster onsprockets driving bush chains rather than rollerchains. This is due to the sliding engagement ofthe bush on the tooth as opposed to the rollingengagement of the roller.
Usually as the sprocket wears, this shows up asa concavity or hooking of the tooth flank. If thisis allowed to continue it will start to impedechain engagement/disengagement and onshort pitch chains weaken the tooth.(See Fig. 22).
Fig. 18
Fig. 21
Fig. 22
Fig. 20
Fig. 19
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If the chain has not been kept in correctadjustment and runs slack it may tend toresonate and jump the teeth, causing the wear
pattern shown in Fig 23. This can be rectified bycorrecting the chain adjustment and ifnecessary replacing the sprocket.
Given adequate lubrication and chainmaintenance, the sprockets should last the lifeof the chain.
Measurement of Tooth Wear
Quite often it is only possible to make visualinspection of the tooth gap. However, if thesprockets are accessible during routinemaintenance, then one of the followingmethods should be used to measure for wear.
i) Clean the tooth gap of oil, grease or anyother matter and apply to the tooth gap an"as new" template. (Fig. 24).
ii) Clean the tooth gap as above and apply asmear of grease around the face of thetooth gap. Hold a piece of stiff paper orcard against the wheel and apply fingerpressure all the way around the tooth gapto form an impression on the paper/card.This can then be compared to the originaltooth gap profile. (Fig. 25).
iii) On larger sprockets, wear can bemeasured by holding a straight edgeagainst the tooth flank and measuring theworn gap. (Fig. 26).
For most conveyor applications, the degree ofwear should not exceed 8% to 10% of thegearing (roller or bush) diameter. In some cases,extended sprocket life can be obtained byturning the sprockets round and allowing the
opposite face to wear (consult Renold foradvice beforehand).
General
As a result of wear between the chain pin andbush, the distance between adjacent rollersincreases more at the outer links than at theinner. In terms of sprocket engagement, thiscauses a greater proportion of the chain pull tobe carried by the most highly loaded tooth. Inthe extreme the full chain pull would be carriedby one tooth, with resulting accelerated toothwear. For this reason it is bad practice to runworn chain on new sprockets or vice versa.
As well as sprocket tooth gap, checks should bemade for signs of unusual wear patterns, i.e.heavy wear or scoring on one side of thesprocket, tapered wear in the tooth gap, etc.
These will indicate chain track, shaft orsprocket misalignments. The causes should beidentified and rectified.
Fig. 23
Fig. 24
Fig. 27
Fig. 26Fig. 25
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Chain Installation and Maintenance
Shafts
The correct alignment of sprockets, shafts andchain tracks is essential for smooth operationof conveyors and satisfactory life of chain andsprockets. The following checks should becarried out before a new conveyor is run, afterchains and/or sprockets have been replaced, orunusual wear patterns are observed on thechain or sprockets. All shafts should be checkedwith a spirit level to make sure they are level.This should be within a gradient of 1/300.
Shafts should also be parallel to each other andperpendicular to the conveyor centre line. Thiscan be checked by measuring between theshaft centres on each side of the conveyor, andalso taking a triangular measurement from a
point on the centre line to equidistant pointson the shaft each side of the centre.
Sprockets should be set at the correct centredistance on each shaft and equidistant aboutthe conveyor centre.
Tracks
Tracks should be checked both individually andacross the set with a spirit level. This should becarried out at regular intervals along theconveyor, i.e. every 1.5m to 2m.
The transverse distance between tracks shouldalso be checked at similar distances along theconveyor, and with reference to a centre line tocheck for side bow.
At the ends of the conveyor, the transversecentres of the tracks and sprockets shouldmatch so that the chain has a smoothtransition from one to the other.
Dismantling & RepairChain
When it becomes necessary to replace links,sections or complete chains, the followingprecautions are necessary:-
a) All power to the conveyor should beisolated before any work is started on thechain.
b) Make sure that the chain is identified andthe correct replacement links are at handbefore breaking the chain.
c) The chain tension should be slackened off
completely so that joints are loose.
d) The sprockets should be prevented fromrotating whilst working on the chain,
especially on inclined conveyorsor elevators.
e) The chain should be suitably restrainedboth sides of the link to be broken, orconnecting link to be removed.
f) Make sure that the necessary safe workingpractices are employed at all times.
It is not recommended that the componentparts of a chain be replaced individually.Repairs should be restricted to replacingcomplete links or lengths of chain only.
Removing a Connecting Link
Connecting links are usually of four main types.
i) Links with thread and nut fastener on oneor both sides.
ii) Links with circlip fasteners on one side.
iii) Links with split pin fasteners on one side.
iv) Riveting links.
To remove a connecting link, the chain shouldbe solidly supported on the conveyor floor or ona bench and the fasteners removed from thebearing pins.
In the case of split pins, it may be necessary to
cut them off flush with the O.D. of the pin.
Fig. 28
Fig. 30
Fig. 29
Fig. 31
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Chain Installation and Maintenance
A sharp blow with a hammer and punch
against the end of each bearing pin in turn willrelease the pins from the link plate and allowthe other plate, complete with pins, to beremoved.
(See Fig. 32 & Fig. 33).
NOTE: If the chain is on a bench or lying on thefloor, the plates should be supported.
Removing a Riveting Link
Support the chain as stated for connecting linksand grind the pin heads on one side of the link,
flush with the link plate. (Fig. 34).To release the pins from the side plate eitheruse a punch and hammer as previously stated,or alternatively, wedge or prise the link platefree of the pin ends. The other plate, completewith pins, can then be removed from the chain.
NOTE: On agricultural chains or small conveyorchains it may be possible to use a transmissionchain type chain breaker.
Complete Chain Replacement
If a chain is worn out and is to be replacedentirely, then either the procedure on page 68can be followed to remove each connecting link
and thus each successive handling length, orthe chain can be cut through with a torch intomanageable sections for disposal.
NOTE: When cutting the chain with a torch, thenecessary safety precautions should befollowed.
Sprockets
Sprockets are usually of three main types.
i) One piece sprockets of steel or cast iron.
ii) Two piece split sprockets.
iii) Sprockets with bolt-on tooth segments.
The vast majority of sprockets in use are of theone piece cast iron or fabricated steel designand are usually parallel or taper keyed to athrough shaft. In this case it is necessary toremove the complete shaft to be able toremove the sprockets. If the sprockets and shafthave been in place for a number of years or theshaft is in hostile conditions, it may be moreeconomical to replace the complete shaft
assembly, rather than try to remove thesprockets from the existing shaft.
Where split sprockets are used it is notnecessary to remove the shaft to be able toreplace a sprocket. After removal of the chain,the sprocket can be dismantled and a new oneassembled around the shaft. This type ofsprocket is particularly useful on multi-strandconveyors where long through shafts are used.Considerable expense can be saved in sprocketreplacement time.
Sprockets with removable tooth segments areparticularly useful where sprocket tooth wear ismuch more rapid than chain wear. With thistype of sprocket, segments of teeth can bereplaced one at a time without having todisconnect or remove the chain from thesprockets, thus considerable expense anddowntime can be saved.
Fig. 35
Fig. 32 Fig.34
Fig. 33
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18 I Installation, maintenance & designer guide
Chain Installation and Maintenance
Wear Strips and Tracks
Wear strips and tracks have an importantinfluence on chain performance and life, asbadly aligned or badly worn wear strips cancause abnormal wear on the conveyor chain.Therefore, it is important that when replacingchain the wear strips are checked and renewedif necessary. Running new chain on worn tracksor wear strips will reduce the life of the chain.
When replacing wear strips, the followingshould be considered:-
i) It is desirable that the chains are slowerwearing than the wear strips as they arethe more critical and expensive items inthe conveyor.
ii) The wear strips should not be as hard asthe chain that is running on it. Bright mildsteel flats are satisfactory for mostapplications. However, under more arduousconditions a harder material can be used.
iii) Wear strips should be flat and level wheninstalled (check with a spirit level). If this isnot the case then chain life will be reducedand conveyor operation could be impaired.(See Fig. 30).
iv) Joints in wear strips or tracks should besmooth so that no sharp edges protrude.
v) Weld spatter, slag, metal filings, scale etc.should be eliminated from the conveyor.
vi) Chain entry and exit points should beradiused to allow smooth transfer of chainsfrom sprockets to tracks.
vii) Non metallic materials such as low frictionplastics can be used where chains aresliding on the chain plate edges, but shouldnot be used where severe impact loads orabrasive conditions exist.
General
a) New chains are usually supplied from thefactory in handling lengths and coiled withone loose joining link per length, so thatthe lengths can be assembled into acomplete endless chain. When installingchains the notes on chain reconnectionshould be followed for joining thehandling lengths together.
b) If the chains have been matched, then oneend of a handling length will be taggedwith a strand letter and connectionnumber (i.e. A3, A4, B3, B4 etc.). Great careshould be taken when assembling thechains that like ends are joined (i.e. A2 to
A3, B2 to B3 etc.), and also that likenumbers are on opposite strands (i.e.A3 opposite B3, A4 opposite B4 etc.). Ifshort lengths are supplied to make thecorrect number of pitches, these aremarked X and Y. The length marked X isassembled on the end of the A chains andthe Y on the B chains. Do not remove thetags until the ends are joined correctly.
c) When handling chains, great care shouldbe taken so that the chains do not get apermanent twist or side bow. This will havean adverse affect on chain operationand life.
d) When chains are supplied with
attachments as handed strands (i.e. righthand and left hand) make sure thatthe chains are connected in the correctorientation.
e) Make sure that connecting links areinstalled with the connector on the correctside of the chain.
Safety Warning
HEALTH AND SAFETY WARNING
1. Always isolate the power source from thedrive or equipment.
2. Always wear safety glasses.
3. Always wear appropriate protectiveclothing, hats, gloves and safety shoes aswarranted by the circumstances.
4. Always ensure tools are in good workingcondition and used in the proper manner.
5. Always loosen tensioning devices.
6. Always support the chain to avoid suddenunexpected movement of chain or
components.7. Never attempt to disconnect or reconnect a
chain unless the chain construction is fullyunderstood.
8. Always ensure that directions for thecorrect use of any tools are followed.
9. Never reuse individual components.
10. Never reuse a damaged chain or chain part.
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Chain Installation and MaintenanceTroubleshooting
EXCESSIVE WEAR IN THE ROLLER BORE
FRACTURED BUSHES
FRACTURED PLATEFRACTURED BEARING PINELONGATED HOLES
LOOSE OR DAMAGEDATTACHMENTS
ROLLER FLATTING DUE TO SKIDDING
TIGHT CHAIN JOINTS
HIGH UNIT LOAD
TWISTED SLATS OR CARRIERS
PACKING OF ABRASIVE PARTICLES
UNSATISFACTORY ROLLER BORELUBRICATION AND CORROSION
SPEED TOO HIGH FOR PITCH
HEAVY SHOCK LOAD APPLIED
CORROSION PITTING
OVERLOAD ABOVE MAXIMUMBREAKING STRENGTH
HIGH UNIT SHOCK LOADING
INCORRECT SLAT OR CARRIER ASSEMBLY
TWISTED CHAIN CAUSING FLEXUREOF PLATFORM BY CONTINUAL SLATOR CARRIER MOVEMENT
TOO LIGHTLY LOADED SYSTEM
HEAVY LOAD WHERE FRICTION BETWEENBUSH AND ROLLER BORE OVERCOMESLEVER EFFECT OF FRICTION AT ROLLER
PERIPHERY EXCESSIVE LUBRICANT ON TRACK
CANTING OF CHAIN DUE TO LOAD
MATERIAL PACKED IN CHAIN
MATERIAL FROZEN IN JOINTS
INCORRECT LUBRICATION (GUMMY)
CORROSION
MALALIGNMENT
PLATE MOVEMENT AFTER BUSHTURNING IN HOLES
DISTRIBUTE LOAD - ALTER PITCH
RECTIFY & CHECK FOR FLATNESS
MINIMISE CHAIN/MATERIALCONTACT - CONSIDER CHAIN ASPULLING MEDIUM ONLY
IMPROVE LUBRICATION; CHANGETO GREASE GUN DESIGN IF POSSIBLE
CHAIN OF SHORTER PITCH BUTEQUIVALENT STRENGTH
INVESTIGATE ON-LOADING INATTEMPT TO MINIMISE SHOCK
CONSIDER SPECIAL MATERIALS ORIMPROVE LUBRICATION
INVESTIGATE FOR FOREIGNOBJECTS CAUSING JAMS
PROTECT CHAIN - SHEAR PIN DEVICE
REVIEW LOADING
MINIMISE SHOCK BY MODIFYING
LOADING SEQUENCE
RE-ALIGN TO ENSURE CORRECTPHASING OF CHAINS
EMPHASISE CARE AT ASSEMBLY STAGE INMOVEMENT OF HANDLING LENGTHS
INCREASE LOAD WITHIN LIMITS OFCHAIN
INCREASE CHAIN SIZE IF NO LOADREDUCTION POSSIBLE
CLEAN AND SCOUR TRACK
STRENGTHEN CARRYING MEDIUM
CLEAN AND RE-LUBRICATE
REDUCE CHAIN/MATERIALCONTACT. RUN CONTINUOUSLY
CLEAN AND LUBRICATE WITHCORRECT TYPE OF LUBRICANT
INVESTIGATE CAUSE ANDCONSIDER SPECIAL MATERIALS
CHECK ALIGNMENT OF STRUCTURE
IMPROVE PIN/BUSH LUBRICATION
ADJUST CORRECTLY
Problem Probable Cause Solution
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Chain Installation and MaintenanceTroubleshooting
CHAIN CLIMBS SPROCKETS
CHAIN CLINGS TO SPROCKETS
EXCESSIVE TOOTH WEAR
BUILD-UP OF EXCESSIVE SLACK
CHAIN ELONGATION
SEVERE OVERLOADS
MATERIAL PACKING BETWEENCHAIN AND SPROCKETS
HEAVY LOAD CARRIED UNDERSPROCKET
INCORRECTTOOTH FORM
WORN TOOTH FORM
HEAVY AND TACKY LUBRICANTS
STIFF CHAIN JOINTS
REPLACE SPROCKETS
ADJUST CHAIN CORRECTLY
REPLACE CHAIN
REDUCE LOADING - STRENGTHENCARRIERS - CONSIDER SPECIALTOOTH FORM
RELIEVED TEETH
CONSTRAIN CHAIN AROUNDSPROCKET
REPLACE
REVERSE SPROCKETS
CLEAN AND RE-LUBRICATE
SEE "TIGHT CHAIN JOINTS"
Problem Probable Cause Solution
CHAIN WHIP EXCESSIVE SLACK
LONG CENTRES WITH PERIODICON-LOADING OF MATERIALCAUSING PULSATING ACTION
FULLY GUIDE RETURN STRAND
General Fault Finding
Problem Probable Cause Solution
EXCESSIVE NOISE
UNEVEN RUNNING
MALALIGNMENT OF TRACK JOINTS
TOO LITTLE OR TOO MUCH SLACK
HIGH SPEED
CHAIN OR SPROCKETS WORN
INEFFECTIVE LUBRICATION
INCORRECT POSITIONING OFGUIDE TRACKS ADJACENT TOSPROCKETS
HEAVY LOAD AND LOW SPEEDCAUSING ROLLERS TO "STICK -SLIP"
VERY LIGHT LOAD AND LUBRICANTON TRACK CAUSING ROLLERS TO"STICK - SLIP"
POLYGONAL ACTION OF CLOSELYSPACED WHEELS IN COMPLEXCIRCUIT
HIGH FRICTION OF IDLER
SPROCKETS POLYGONAL ACTION ON
SPROCKETS
CHECK ALIGNMENT OFSTRUCTURE
ADJUST CORRECTLY
CONSIDER SHORTER PITCH
REPLACE
LUBRICATE
REPOSITION
SEE "ROLLER FLATTING".CONSIDER ADDITIONAL DRIVE POINT.CHECK SURGE AT DRIVE DUE TOINADEQUATE POWER RESERVE ORSHAFT/BEARING RIGIDITY
GUIDES TO BE CLEANED TOREMOVE EXCESS LUBRICANT ANDCHAIN LUBRICATED ON ROUNDPART CONTACT POINTS ONLY
INCREASE SPROCKET CENTRESOR REPOSITION SPROCKETS
LUBRICATE CORRECTLY OR FIT
LOW FRICTION BEARINGS INTRODUCE SPROCKETS WITH A
LARGER NUMBER OF TEETH
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Section 2Conveyor Chain Designer Guide
Renold Conveyor Chain Catalogue I 21
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Designer GuideIntroduction
Selecting the right chain for a given application
is essential to obtain long service life. Thisguide has been developed for use with Renoldconveyor chain to help in specifying the rightchain and lubrication for your conveyor system.The significance of the Renold conveyor chaindesign is emphasised, followed by guidance onselection procedure. Detailed descriptions aregiven of the various methods of application in avariety of mechanical handling problems andunder widely varying conditions. Thesupporting material includes various referencetables and statistics.
From the pyramids to the railway revolution,muscle-power of men and animals has movedgoods and materials, but throughout history,
machines, however primitive, have played somepart, becoming more and more versatile.
Within the immediate past, mechanicalhandling has emerged asa manufacturing industry in its own right, ofconsiderable size and with countlessapplications. This is a consequence of itscoverage, which now ranges from the simpleststore conveyor system to the largest flow lineproduction layouts, and also includes themovement of personnel by lifts, escalators andplatforms.
Amongst the most widely used types ofhandling equipment are conveyors, elevatorsand similar assemblies. These can takemany forms, employing as their basic movingmedium both metallic and non-metallic
components or a mixture of the two.For the great majority of applications Renoldconveyor chain in its many variations, whenfitted with suitable attachments, provides ahighly efficient propulsion and/or carryingmedium, having many advantages over othertypes. Roller chain has been employed asan efficient means of transmitting power sinceit was invented by Hans Renold in 1880. Laterthe principle was applied to conveyor chaingiving the same advantages of precision, heat-treated components to resist wear, highstrength to weight ratio and high mechanicalefficiency.`
Renold conveyor chain is made up of a series ofinner and outer links. Each link comprisescomponents manufactured from materials bestsuited to their function in the chain; thevarious parts are shown in Figure 1. An innerlink consists of a pair of inner plates which arepressed onto cylindrical bushes, whilst on eachbush a free fitting roller is normally assembled.Each outer link has a pair of outer plates whichare pressed onto bearing pins and the ends ofthe pins are then rivetted over the plate.
From the foregoing, it will be seen that a length
of chain is a series of plain journal bearings freeto articulate in one plane. When a chainarticulates under load the friction between pinand bush, whilst inherently low because of thesmooth finish on the components, will tend toturn the bush in the inner plates and similarlythe bearing pin in the outer plate. To preventthis the bush and pin are force fitted into thechain plates. Close limits of accuracy areapplied to the diameters of plate holes, bushesand bearing pins, resulting in high torsionalsecurity and rigidity of the mating components.Similar standards of accuracy apply to the pitchof the holes in the chain plates.
To ensure optimum wear life the pin and bush
are hardened. The bush outside diameter ishardened to contend with the load carryingpressure and gearing action, both of which areimparted by the chain rollers. Chain rollermaterial and diameter can be varied and areselected to suit applicational conditions;guidance in roller selection is given on page 80.Materials used in chain manufacture conformto closely controlled specifications.Manufacture of components is similarlycontrolled both dimensionally and with regardto heat treatment.
For a given pitch size of transmission chain,there is normally a given breaking load.However, conveyor chain does not follow this
convention. For each breaking load, conveyorchain has multiple pitch sizes available. Theminimum pitch is governed by the need for
adequate sprocket tooth strength, themaximum pitch being dictated by plate andgeneral chain rigidity. The normal maximumpitch can be exceeded by incorporatingstrengthening bushes between the link plates,and suitable gaps in the sprocket teeth to clearthese bushes.
CHAIN TYPES
There are two main types of conveyor chain -hollow bearing pin and solid bearing pin.
Hollow Bearing Pin Chain
Hollow pin conveyor chain offers the facility forfixing attachments to the outer links usingbolts through the hollow pin and attachment,this method of fixing being suitable for use inmost normal circumstances. The attachmentsmay be bolted up tight or be held in a freemanner. Bolted attachments should only spanthe outer link as a bolted attachment spanningthe inner link would impair the free articulationof the chain.
RENOLD
Fig. 1
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Solid Bearing Pin Chain
Solid bearing pin chain, while having exactlythe same gearing dimensions in the BS series ofchain as the equivalent hollow pin chain,i.e.pitch, inside width and roller diameter, ismore robust with a higher breaking load and isrecommended for use where more arduousconditions may be encountered.
Deep Link Chain
Hollow and solid pin chain has an optional sideplate design known as deep link. This chainsside plates have greater depth than normal,thus providing a continuous carrying edgeabove the roller periphery.
INTERNATIONAL STANDARDS
Conveyor chain, like transmission chain, can bemanufactured to a number of differentinternational standards. The main standardsavailable are:
British Standard - BS
This standard covers chain manufactured tosuit the British market and markets where astrong British presence has dominatedengineering design and purchasing. Thestandard is based on the original Renoldconveyor chain design.
ISO Standard
Chain manufactured to ISO standards is notinterchangeable with BS or DIN standard chain.This standard has a wide acceptance in theEuropean market, except in Germany. Chainmanufactured to this standard is becomingmore popular and are used extensively in the
Scandinavian region.
CHAIN ATTACHMENTS
An attachment is any part fitted to the basicchain to adapt it for a particular conveyingduty, and it may be an integral part of thechain plate or can be built into the chain as areplacement for the normal link.
K Attachments
These are the most popular types ofattachment, being used on slat and apronconveyors, bucket elevators etc. As shown inFig. 2 they provide a platform parallel to thechain and bearing pin axes. They are used forsecuring slats and buckets etc. to the chain.
Either one or two holes are normally providedin the platform, being designated K1 or K2respectively. K attachments can be incorporatedon one or both sides of the chain. For the moreimportant stock pitches where large quantities
justify the use of special manufacturingequipment, the attachments are produced asan integral part of the chain, as shown in Fig.2(a). Here the platform is a bent over extensionof the chain plate itself.
On other chain or where only small quantitiesare involved, separate attachments are used, asshown in Fig. 2(b). These are usually welded tothe chain depending on the particular chainseries and the application. Alternatively, (seeFig 2(c)), K attachments may be bolted to thechain either through the hollow bearing pins,or by using special outer links with extendedand screwed bearing pin ends.
(a) K1 bent over attachment.
(b) K1 attachment, welded to link plate.
(c) K2 attachment bolted through hollowbearing pin.
F Attachments
These attachments as shown in Fig. 3 arefrequently used for pusher and scraper
applications. They comprise a wing with avertical surface at right angles to the chain.They can be fitted to one or both sides and are
usually secured by welding. Each wing can be
provided with one or two holes, beingdesignated F1 or F2 respectively.
(a) F1 attachments welded to link plates onone or both sides of the chain as required.
(b) F2 attachments welded to link plates onone or both sides of the chain as required.
Spigot Pins and Extended Bearing Pins
Both types are used on pusher and festoonconveyors and tray elevators, etc. Spigot pinsmay be assembled through hollow bearingpins, inner links or outer links. When assembledthrough link plates a spacing bush is necessaryto ensure that the inside width of the chain isnot reduced. Gapping of the sprocket teeth isnecessary to clear the bush.
Solid bearing pin chains can have similar
extensions at the pitch points by incorporatingextended pins. Both spigot pins and extendedpins, as shown in Fig. 4, can be case-hardenedon their working diameters for increased wearresistance.
(a) Spigot pin assembled through outer orinner link.
(b) Spigot pin bolted through hollow bearingpin.
(c) Extended bearing pin.
RENOLDRENOLD
RENOLDRENOLD RENOLDRENOLD
RENOLD
RENOLD
RENOLD
RENOLD
RENOLD
RENOLD
RENOLD
c
Fig.2
a b
c
Fig.4
a b
Fig.3
a b
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Staybars
Types of mechanical handling equipment thatuse staybars are pusher, wire mesh, festoonconveyors, etc., the staybars being assembled inthe same manner as spigot pins. Whenassembled through link plates a spacing bushand gapping of the sprocket teeth arenecessary.
The plain bar-and-tube type shown in Fig. 5 hasthe advantage that the staybar can beassembled with the chain in situ by simplythreading the bar through the chain and tube.The shouldered bar type has a greater carryingcapacity than the bar-and-tube type. Staybarsare normally used for either increasing overallrigidity by tying two chains together,maintaining transverse spacing of the chains,or supporting loads.
(a) Staybar bolted through hollow bearing pin.
(b) Staybar assembled through outer or inner
link.
G Attachments
As shown in Fig. 6 this attachment takes theform of a flat surface positioned against theside of the chain plate and parallel to the chainline. It is normally used for bucket elevatorsand pallet conveyors. When the attachment isintegral with the outer plate then the shroud ofthe chain sprocket has to be removed to clearthe plate. G Attachments are normally fittedonly to one side of the chain.
(a) G2 attachment outer plate.
(b) G2 attachment, welded or rivetted to linkplate.
L Attachments
These have some affinity with the Fattachment, being in a similar position on the
chain. A familiar application is the box scraperconveyor. As shown in Fig. 7 the attachmentsare integral with the outer plates, being
extended beyond one bearing pin hole and
then bent round. The attachments can be plainor drilled with one or two holes, beingdesignated L0, L1 or L2 respectively. They can besupplied on one or both sides of the chain.With this type of attachment the chain rollersare normally equal to the plate depth, or a bushchain without rollers is used.
L2 attachments on both sides of the outer link.
S and Pusher Attachments
These are normally used on dog pusherconveyors. As shown in Fig. 8 the S attachmentconsists of a triangular plate integral with thechain plate; it can be assembled on one or bothsides of the chain, but may also be assembledat the inner link position. S attachments areintended for lighter duty, but for heavier duty apair of attachments on one link is connected bya spacer block to form a pusher attachment.This increases chain rigidity and pushing area.
(a) S attachment outer plate; assembled onone or both sides of chain as required.
(b) Pusher attachment.
Drilled Link Plates
Plates with single holes as shown in Fig. 9(a)are associated with the fitting of staybars orspigot pins. Where G or K attachments are tobe fitted then link plates with two holes asshown in Fig. 9(b) are used. Where attachmentsare fitted to inner links then countersunk boltsmust be used to provide sprocket toothclearance.
Outboard Rollers
The main reasons for using outboard rollers arethat they increase roller loading capacity of thechain and provide a stabilised form of loadcarrier. As shown in Fig. 10 the outboard rollersare fixed to the chain by bolts which passthrough hollow bearing pins. Outboard rollershave the advantage that they are easilyreplaced in the event of wear and allow thechain rollers to be used for gearing purposesonly.
Chain Joints
Conveyor chain is normally supplied inconvenient handling lengths, these being
joined by means of outer connecting links. Thiscan be accomplished by the use of any of thefollowing:
No. 107
Outer link used for rivetting chain endless. It isparticularly useful in hollow bearing pin chainswhere the hollow pin feature is to be retained.
No. 69
Bolt-type connecting linkwith solid bearing pin. Loose plate is a slip fiton the bearing pins and retained by self lockingnuts
.
RENOLD
RENOLD
RENOLD
RENOLD
Fig.5
RENOLD
RENOLD
Fig.7
RENO
LD
RENO
LD
Fig. 10 Outboard Rollers
a b
Fig.8
a
Fig. 11
No.107
b
Fig.9
a b
Fig.6
a b
No. 69
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No. 58
On lower breaking strength chain a soft circlipretains the connecting plate in position on thepins, the connecting plate being an interferencefit on the bearing pins.
No. 86
A modified version of the bolt-type connecting
link. The connecting pins are extended topermit the fitment of attachments on one sideof the chain only.
No. 11
For 4,500 lbf series chain only, circlips are fittedto both ends of hollow connecting pins.
No. 85
Similar to No. 86 but allows attachments to bebolted to both sides of the chain.
Advantages of Renold Conveyor Chain
These can be summarised as follows:-
a. Large bearing areas and hardenedcomponents promote maximum life.
b. Low friction due to a smooth finish of thecomponents.
c. The inclusion of a chain roller and the highstrength to weight ratio enable lighter
chain selection and lower powerconsumption.
d. The use of high grade materials ensuresreliability on onerous and arduousapplications.
e. The facility to obtain a variety of pitcheswith each chain breaking strength and avariation in attachment types providesadaptability.
f. The accuracy of components providesconsistency of operation, accurate gearingand low sprocket tooth wear. The latter isparticularly important in multi-strandsystems where equal load distribution is
vital.
Basic Requirements
To enable the most suitable chain to beselected for a particular application it isnecessary to know full applicational detailssuch as the following:
Type of conveyor.
Conveyor centre distance and inclination fromthe horizontal.
Type of chain attachment, spacing and methodof fixing to the chain.
Number of chains and chain speed.
Details of conveying attachments, e.g. weightof slats, buckets, etc.
Description of material carried, i.e. weight, sizeand quantity.
Method of feed and rate of delivery.
Selection of Chain Pitch
In general the largest stock pitch possibleconsistent with correct operation should beused for any application, since economicadvantage results from the use of the reducednumber of chain components per unit length.Other factors include size of bucket or slats etc.,chain roller loading (see Page 76) and thenecessity for an acceptable minimum number
of teeth in the sprockets where spacerestriction exists.
Chain Pull Calculations
The preferred method of calculating thetension in a conveyor chain is to consider eachsection of the conveyor that has a differentoperating condition. This is particularlynecessary where changes in direction occur orwhere the load is not constant over the wholeof the conveyor.
For uniformly loaded conveyors there is aprogressive increase in chain tension fromtheoretically zero at A to a maximum at D. This
is illustrated graphically in Fig. 14 where thevertical distances represent the chain tensionoccurring at particular points in the circuit, thesummation of which gives the total tension inthe chain.
Thus, in Fig. 14 the maximum pull at D
comprises the sum of:
(a) Pull due to chain and moving parts on theunloaded side.
(b) Extra pull required to turn the idlerwheels and shaft.
(c) Pull due to chain and moving parts on theloaded side.
(d) Pull due to the load being moved.
If it is imagined that the chains are cut atposition X then there will be a lower load pullor tension at this position than at Y. This fact issignificant in the placing of caterpillar drives in
complex circuits and also in assessing tensionloadings for automatic take-up units.
This principle has been used to arrive at theeasy reference layouts and formulae (Page 83 -84) to which most conveyor and elevatorapplications should conform. Where conveyorsdo not easily fit these layouts and circuits aremore complex then see page 85 or consultRenold Applications Department for advice.
Factors of safety
Chain manufacturers specify the chain in theirproduct range by breaking load. Some havequoted average breaking loads, some have
quoted minimum breaking loads dependingupon their level of confidence in their product.Renold always specify minimum breaking load.To obtain a design working load it is necessaryto apply a factor of safety to the breakingload and this is an area where confusion hasarisen.
As a general rule, Renold suggest that for mostapplications a factor of safety of 8 is used,
Working Load = Breaking Load
8
Fig. 12
No. 58 No. 86
Fig. 13
No. 11 No. 85
Travel
C
B
Y
D
Driver
Total chain tension
X
A
Fig. 14
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On first inspection, a factor of safety of 8 seems
very high and suggests that the chain could beover-selected if this factor is applied.
If, however, we examine the situation in detail,the following points arise:-
1. Most chain side plates are manufacturedfrom low or medium carbon steel and aresized to ensure they have adequatestrength and resistance to shock loading.
2. These steels have yield strengths that varyfrom 50% to 65% of their ultimate tensilestrength. This means that if chains aresubjected to loads of 50% to 65% of theirbreaking load, then permanent pitchextension is likely to occur.
3. It is the tendency to over-select drive sizesjust to be sure the drive is adequate, andthe motors used today are capable of up to200% full load torque output for a shortperiod.
4. The consequences of this are that a chainconfidently selected with a factor of safetyof 8 on breaking load is in effect operatingwith a factor of safety of as low as 4 on the
yield of the material, and 2 when thepossible instantaneous overload on thedrive is considered, and this is withoutconsidering any over-selection of the motornominal power.
5. A further consideration when applying afactor of safety to a chain application is thechain life.
The tension applied to a chain is carried by thepin/bush interface which at the chain sprocketsarticulates as a plain bearing.
Experience has shown that, given a goodenvironment, and a clean and well lubricatedchain, a bearing pressure of up to 24N/mm2
(3500 lb/inch2) will give an acceptablepin/bush life. A safety factor of 8 will give thisbearing pressure.
In anything other than a clean well lubricated
environment the factor of safety should beincreased, thus lowering the bearing pressure,if some detriment to the working life of thechain is to be avoided.
Table 1 gives a general guide to the appropriatesafety factors for different applications.
Table 1 - Factors of Safety
CLEANLINESS/LUBRICATION
TEMPERATURE/LUBRICATION
In all the listed applications and conditions, theincrease in factor of safety is applied with theobject of lowering the pin/bush bearingpressure to improve the chain life.
Chain Life
There are a number of factors affecting the lifeof a chain in a particular environment.
a. The load on the chain and therefore thebearing pressure between the pin and thebush.The design of conveyor chain is such that at
the calculated working load of the chain(relative to the breaking load) then thebearing pressure between the pin and thebush will be at a maximum of 24N/mm2
(3500lb/in2) for a clean well lubricatedenvironment.This pressure should be reduced foranything less than clean, well lubricatedconditions and this is allowed for byincreasing the factor of safety as shown intable 1.
b. The characteristics of the material handled,i.e. abrasiveness, etc.Some materials are extremely abrasive andif the material cannot be kept away from
the chain then the bearing pressure mustbe reduced to lessen the effect of theabrasion. It is possible to improve the
abrasion resistance of chain components
by more sophisticated heat treatments atextra cost but the usual way of ensuring anacceptable life is to reduce the bearingpressure. See page 101 for the abrasivecharacteristics of materials. In someinstances it is possible to use block chain toimprove chain life, see page 91.
c. Corrosion.Some materials are aggressive to normalsteels and the nature of the attack will beto reduce the side plate section andtherefore the chain strength, or causepitting of the pin, bush and roller surfaces.The pitting of the surface has the effect of
reducing the bearing area of thecomponent and therefore increasing thebearing pressure and wear rate. Theprocess will also introduce (onto thebearing surfaces) corrosion products whichare themselves abrasive.Materials such as Nitrates will cause thefailure of stressed components due tonitrate stress cracking.Page 107 shows some materials togetherwith their corrosive potential for variouschain materials.
d. Maintenance by the end user is one of themost important factors governing the lifeof a chain.
For the basic maintenance measuresrequired to obtain the maximum useful lifefrom your chain consult the Installationand Maintenance section.
LOAD
EXTENSION
MATERIAL
YIELD, POINT
P
O(a)
EXTENSION
PERMANENT
Fig. 15
Lu bric ation Clean Moderatel y Dirty Abrasi veClean
Regular 8 10 12 14
Occasional 10 12 14 16
None 12 14 16 18
Lubrication -30 / +150C 150 - 200C 200 - 300C
Regular 8 10 12
Occasional 10 12 14
None 12 14 16
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Assessment of chain roller friction
In conveyor calculations the value of thecoefficient of friction of the chain roller has aconsiderable effect on chain selection. When achain roller rotates on a supporting track thereare two aspects of friction to be considered.Firstly there is a resistance to motion caused byrolling friction and the value for a steel rollerrolling on a steel track is normally taken as0.00013. However this figure applies to theperiphery and needs to be related to the rollerdiameter, therefore:
Secondly a condition of sliding friction existsbetween the roller bore and the bush periphery.For well lubricated clean conditions acoefficient of sliding friction Fof 0.15 is usedand for poor lubrication approaching theunlubricated state, a value of 0.25 should beused. Again this applies at the bush/rollercontact faces and needs to be related to their
diameters.
Coefficient of sliding friction =
Fx Roller bore (mm)
Roller diameter (mm)
Thus the overall theoretical coefficient of chainrollers moving on a rolled steel track =
0.26 + (Fx Roller bore) (mm)
Roller diameter (mm)
In practice, a contingency is allowed, to accountfor variations in the surface quality of thetracking and other imperfections such as track
joints. The need for this is more evident asroller diameters become smaller, and thereforethe roller diameter is used in an additional partof the formula, which becomes:
Overall coefficient of friction =
C= 0.26 + (Fx d) + 1.64
D D
and simplified: C= 1.90 + Fd
D
Where C= overall coefficient of friction forchain.
F= bush/roller sliding frictioncoefficient.
d = roller bore diameter in mm.
D = roller outside diameter in mm.
The formula is applicable to any plain bearingroller but in the case of a roller having ball,roller or needle bearings the mean diameter ofthe balls etc. (Bd), would be used as the rollerbore. Fis taken as 0.0025 to 0.005, the latterbeing assumed to apply to most conditions.Thus overall coefficient of friction for a chainroller fitted with ball bearings and rolling on asteel track:
The following table shows values for overallcoefficient of friction for standard conveyorchain with standard rollers (c). Alternativevalues can be calculated as above if the rollerdiameter is modified from the standard shown.
OVERALL COEFFICIENTS OF ROLLING FRICTION
FOR STANDARD CONVEYOR CHAIN (c)
Coefficient of rolling friction =
0.00013 = 0.13
Roller radius (m) Roller radius (mm)
= 0.26
Roller diameter (mm)
c= 0.26 + (0.005 x Mean diameter of balls (mm))
Roller diameter (mm)
+
1.64
Roller diameter (mm)
. . .c= 1.90 + (0.005 x Bd)
D
D
dChain Pull
Sliding Friction
Rolling Friction
Bush/Roller clearance(exaggerated)
Roller
BushF
Fig. 16
Bd
Fig. 17
Chain U lt imate Ro ll er Chain Overall Coefficient of Frictionc
Reference Strength Diameter(kN) (mm)
Re gu lar O cc asi ona l N o
DLubrication Lubrication LubricationF= 0.15 F= 0.20 F= 0.25
BS Series
BS13 13 25.4 0.13 0.14 0.16
BS20 20 25.4 0.15 0.17 0.19
BS27/BS33 27/33 31.8 0.15 0.18 0.20
BS54/BS67 54/67 47.6 0.12 0.14 0.17
BS107/BS134 107/134 66.7 0.10 0.13 0.15
BS160/BS200 160/200 88.9 0.09 0.11 0.13
BS267 267 88.9 0.09 0.11 0.13
BS400 400 88.9 0.09 0.11 0.13
ISO Series
M40 40 36 0.11 0.12 0.14
M56 56 42 0.10 0.12 0.14
MC56 56 50 0.10 0.12 0.14
M80 80 50 0.09 0.11 0.13
M112 112 60 0.09 0.10 0.12
MC112 112 70 0.09 0.11 0.13
M160 160 70 0.08 0.10 0.12
M224 224 85 0.08 0.09 0.11
MC224 224 100 0.08 0.10 0.12
M315 315 100 0.07 0.09 0.11
M450 450 120 0.07 0.09 0.10
M630 630 140 0.07 0.09 0.10
M900 900 170 0.06 0.08 0.10
Table 2
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ROLLER SELECTION AND ROLLER LOADING
CONSIDERATIONS
Roller Selection
Roller Materials
1. Unhardened mild steel rollers are used inlightly loaded, clean and well lubricatedapplications subject to occasional use.
2. Hardened steel rollers are used in themajority of applications where a hardwearing surface is required.Note that through hardened sinteredrollers are standard on BS chain of 26 to67kN breaking load. On all other BS and on
ISO chain the standard hardened rollers arein case hardened mild steel.
3. Cast iron rollers are used in applicationswhere some corrosion is likely and ameasure of self-lubrication is required.
4. Synthetic rollers, e.g. Delrin, nylon or otherplastics can be used where either noise orcorrosion is a major problem. Pleaseenquire.
Roller Sizes and Types
1. Small (gearing) rollers are used for sprocketgearing purposes only to reduce abrasionand wear between chain bush and sprockettooth. These rollers do not project andconsequently, when not operatingvertically, the chain will slide on the sideplate edges.
2. Standard projecting rollers are used formost conveying applications and aredesigned to operate smoothly withoptimum rolling friction properties. Theycreate an acceptable rolling clearanceabove and below the chain side plates.
3. Flanged rollers are used where extraguidance is required or where imposed sideloads would otherwise force the chain outof line.
4. Larger diameter rollers are occasionallyused where the greater diameter of theroller reduces wear by reducing the rubbingvelocity on the chain bushes and promotessmoother running at slow speeds.These rollers can be either plain or flangedin steel, cast iron or synthetic material.
5. Most chain can be supplied with ballbearing rollers either outboard or integral.This special design option can be justifiedby the selection of a lower breaking loadchain in many applications and a reductionin the drive power required.
Roller Loading (Bush/Roller Wear)
In the majority of cases a conveyor roller chainwill meet bush/roller wear requirements if ithas been correctly selected using factors ofsafety on breaking load. Doubt can arise whereheavy unit loading is involved, which couldcause the bearing pressure between the chainbush and roller to be excessively high, or wherethe chain speed may exceed the recommendedmaximum. In such cases further checks have tobe made.
Bush/Roller Bearing Areas and BearingPressures
The bush/roller bearing areas for standard BSand ISO series conveyor chain are as follows:
Bush/Roller Bearing Area BS
Ch ain Reference Bearin g Area mm2
BS13 99
BS20 143
BS27 254
BS33 254
BS54 420
BS67 420
BS107 803
BS134 803
BS160 1403
BS200 1403
BS267 1403
BS400 1403
Table 3
Bush/Roller Bearing Area - ISO
Ch ain Reference Bearin g Area mm2
M40 232
M56 333
MC56 447
M80 475
M112 630
MC112 850
M160 880
M224 1218
MC224 1583
M315 1634
M450 2234
M630 3145
M900 4410
Table 3 (Continued)
Bearing Pressure
Normal maximum permitted bearing pressuresfor chain speeds up to 0.5m/sec., and inreasonably clean and lubricated applicationsare listed below:
Roller Bearing Pressure P
Material Normal Maximum
Mi ld ste el case hardene d 1.8N/mm2
Sintered steel through hardened 1 .2N/mm2
Cast iron 0.68N/mm2
Table 4
The formula:bearing pressure P (N/mm2) =
roller load R (N)
Bearing area BA (mm2)
is used first to check whether actual pressureexceeds the above recommendation. If it does,or if the conveyor speed exceeds 0.5m/sec, thechain may still be acceptable if alternativeconditions can be met. These depend upon acombination of bearing pressure and rubbingspeed between bush and roller, known as thePVRvalue, and the degree of cleanliness and
lubrication on the application. If cleanlinessand lubrication are much better than averagefor example, higher bearing pressures and PVRvalues than normal can be tolerated. In order tomake this judgement the following table isused, along with the formula:
Rubbing Speed VR(m/sec) =
Chain Speed (m/sec) x Bush diameter (mm)
Roller Diameter (mm)
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Table 5
If the rubbing speed is above 0.15 m/s,calculate the PVRvalue to see if it is below the
max value in the table. If the rubbing speed isbelow 0.15 calculate the bearing pressure tosee if it is below the maximum given in thetable. If the speed is below 0.025 m/s it is bestto use rollers with an o/d to bore ratio of 3 orhigher, or use ball bearing inboard or outboardrollers with the required load capacity.
If the calculated bearing pressure or PVRexceeds the guidelines given in the tablesthen consider one of the following:
a. Use a larger chain size with consequentlylarger rollers.
b. Use larger diameter rollers to reduce therubbing speed.
c. Use outboard rollers, either plain or ballbearing.
d. Use ball bearing rollers.
e. If in doubt consult Renold.
Stick Slip
Stick-Slip is a problem that occurs in someslow moving conveyor systems which results inirregular motion of the chain in the form of apulse. Stick slip only occurs under certainconditions and the purpose of this section is tohighlight those conditions to enable the
problem to be recognised and avoided. For aconveyor running at a linear speed of approx.0.035m/sec or less, one of the most often
encountered causes of stick-slip is over-
lubrication of the chain. Too much oil on thechain leads to the chain support tracks beingcoated with oil thus loweringR1, (Fig. 18). Ifany of the other stick-slip conditions arepresent then R1is insufficient to cause theroller to turn against the roller/bush friction Fand the roller slides along on a film of oil.
The oil film builds up between the bush androller at the leading edge of the pressurecontact area and the resulting vacuumcondition between the two surfaces requiresforce to break it down. If the chain tracks arecoated with oil, or oil residue, then this force isnot immediately available and the roller slides
along the track without rotating. The vacuumthen fails, either due to the static condition ofthe bush/roller surfaces or by the breakdownof the dynamic film of lubricant on the track.
In either case the change from the sliding stateto rotation causes a pulse as the velocity of thechain decreases and then increases.
Once rotation returns then the cycle is repeatedcausing regular pulsations and variations ofchain speed. Although the friction isinsufficient to cause the roller to turn, frictionis present and, over a period, the roller willdevelop a series of flats which will compoundthe problem.
The other features that are necessary for stickslip to occur are:
a. Light loading - If the loading on the roller isvery light then it is easy for a vacuumcondition to develop. Heavy loads tend tobreak the oil film down on the chain tracks.
b. Irregular loading - If the chain is loaded atintervals, with unloaded gaps, it is possiblefor the chain between the loadsto experience stick slip due to light loading.
Precautions to Avoid Stick Slip
1. Avoid speeds in the critical range up toapprox. 0.035m/sec., if possible.
2. Avoid irregular loading, if possible.
3. If it is not possible to avoid the speed andloading criticality, then great care should betaken in system design:
3.1 Control the application of lubricant toavoid track contamination.
3.2 If light loads are to be carried thenchain rollers should be either larger
than standard or be fitted with ballbearings to lower the bush/rollerfriction,F, or improve mechanicalefficiency.
As a rough guide, where plain (not ball bearing)rollers are used, a ratio of roller diameter tobush diameter of 2.7:1 or greater shouldeliminate stick slip at the critical speeds.
TRACKED BENDS
Where chain is guided around curves there isan inward reaction pressure acting in the
direction of the curve centre. This applieswhether the curved tracks are in the vertical orhorizontal planes, and, relative to the former,whether upwards or downwards in direction.The load pull effect resulting from the chaintransversing a curved section, even if this be inthe vertical downward direction, is alwaysconsidered as a positive value, i.e. serving toincrease the chain load pull.
An analogy is a belt on a pulley whereby theholding or retaining effect depends upon theextent of wrap-around of the belt, and frictionbetween the belt and pulley.
Similarly there is a definite relationship
between the tension or pull in the chain atentry and exit of the curve. Referring to thediagrams this relationship is given by:
P2= P1ec
Where P1 = Chain pull at entry into bend (N)
P2= Chain pull at exit from bend (N)
e = Naperian logarithm base (2.718)
c= Coefficient of friction betweenchain and track
= Bend angle (radians)
Ro ll er Rubbing speed Ma x. B ea ring Pre ssureMaterial VR(m/sec) P (N/mm2)
Very Good Average Very Good AverageConditions Conditions Conditions Conditions
Casehardened 0 .025 - 0 .15 0 .025 - 0 .25 10.35 1 .80mild s teel over 0 .15 over 0 .25 use PVR=1.55 use PVR=0.45
Sinteredthro ugh- 0.025 - 0.15 0 .02 5 - 0 .25 6.90 1.20
hardenedsteel over 0.15 over 0.25 use PVR=1.04 use PVR=0.30
Ca st i ron 0.025 - 0.15 0 .02 5 - 0 .25 3.91 0.68over 0.15 over 0.25 use PVR=0.59 use PVR=0.17
Bush/Roller Clearance(Exaggerated)
Roller
Bush
od
W (kg)
F
R 1
id
Fig. 18
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The above formula applies whether the chain istracked via the chain rollers or by the chainplate edges bearing on suitable guide tracks.Table 6 gives values of ec.
Since high reaction loadings can be
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